CN215135920U

CN215135920U - Electromagnetic heart beating assisting device

Info

Publication number: CN215135920U
Application number: CN202120817542.3U
Authority: CN
Inventors: 曾建新
Original assignee: Shenzhen Maiteng Medical Technology Co ltd
Current assignee: Shenzhen Maiteng Medical Technology Co ltd
Priority date: 2021-04-20
Filing date: 2021-04-20
Publication date: 2021-12-14
Anticipated expiration: 2031-04-20

Abstract

The utility model relates to the technical field of medical equipment, specifically electromagnetic type heart beats auxiliary device, include: the heart-shaped support comprises an inner membrane, an outer membrane support body, two permanent magnets, an electromagnet, a power supply and a controller, wherein the inner membrane is coated on the surface of a heart, the outer membrane support body covers the outer side of the inner membrane, the two permanent magnets are fixed on the outer side of the inner membrane and respectively correspond to a left ventricle and a right ventricle, the two electromagnets are fixed on the inner side of the outer membrane support body and are arranged opposite to the permanent magnets, and the power supply and the controller are used for supplying power to the electromagnet and adjusting the current magnitude and direction, so that the electromagnet can apply repulsion force or suction force to the permanent magnets to drive the heart to contract or relax. The advantage of this patent is, can assist the human heart to beat, and the controllability is strong, improves the heart failure symptom, prolongs patient's life-span, and simple structure, small in size only needs surgery to implant, and it is convenient to change, makes low in use cost, long service life, and doctor patient easily accepts.

Description

Electromagnetic heart beating assisting device

Technical Field

The utility model relates to the technical field of medical equipment, in particular to an electromagnetic heart beating assisting device.

Background

Heart failure (heart failure) refers to a heart circulatory disturbance syndrome caused by insufficient discharge of venous return blood volume from the heart due to the failure of the systolic function and/or diastolic function of the heart, resulting in venous system blood stasis and arterial system blood perfusion deficiency, wherein the disturbance syndrome is manifested as pulmonary congestion and vena cava congestion. Heart failure is not an independent disease but the terminal stage of progression of heart disease. Most of these heart failures begin with left heart failure, which manifests itself primarily as pulmonary circulation congestion. The survival rate of the heart failure treatment drug for two years is about 80 percent, and the survival rate for five years is only about 50 percent. The treatment of heart failure must seek a breakthrough to save a large number of people who die frequently.

At present, the intra-aortic balloon counterpulsation is effective for patients with low cardiac output and heart failure especially combined with cardiogenic shock, but is not suitable for long-term use because the equipment is heavy and cannot be carried. Most of foreign artificial heart research focuses on simulating heart structures, the heart of a patient needs to be replaced and cut off, due to insufficient energy supply, although the artificial heart is applied to clinic, the death risk of the patient is high, the life is short, and finally the artificial heart is difficult to popularize because the service life is short, the complications are many and are not accepted by the patient. Heart transplantation is often difficult to implement widely due to donor shortage, large surgical trauma, high cost, and high immune rejection.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defect that exists among the prior art, the utility model discloses a task is to provide electromagnetic type heart beat auxiliary device, can promote human systole or diastole voluntarily, supplementary human heart beats, and the controllability is strong, make the normal pump blood function of human heart recovery, can improve the heart failure symptom, prolong patient's life-span, have very important using value, and simple structure, small in size, do not need to excise the heart, only need the surgery to implant, and the change is convenient, low in use cost, long service life, doctor patient easily accepts.

The utility model discloses the task is realized through following technical scheme:

an electromagnetic heart beat assist device includes:

the inner membrane is coated and fixedly connected on the surface of the heart of a human body when in use;

the outer membrane support body covers the outer side of the inner membrane and has a gap with the inner membrane when in use, and the edge of the outer membrane support body is fixedly connected with the surface of the heart of the human body;

the permanent magnets are fixedly connected to the outer side of the inner membrane, the number of the permanent magnets is at least two, at least one permanent magnet is positioned on the outer side of the left ventricle of the human heart, and at least one permanent magnet is positioned on the outer side of the right ventricle of the human heart;

the electromagnets are fixedly connected to the inner side of the outer membrane support body and can be supported and fixed through the outer membrane support body, and the electromagnets and the permanent magnets are in one-to-one correspondence and are oppositely arranged when the electromagnet support device is used;

and the power supply and the controller are connected with the electromagnet through electric wires and used for supplying power to the electromagnet and adjusting the current magnitude and direction, so that the electromagnet can apply repulsion or attraction to the corresponding permanent magnet, and further the heart of the human body is driven to contract or relax.

As a preferable technical solution, the electromagnetic heart beat assisting device further includes a sensor, the sensor is connected to the controller, and the sensor can monitor the heart beat rhythm of the human body in real time and send data to the controller, so that the controller controls the electromagnet to apply a repulsive force to the permanent magnet to promote the contraction of the human body when the heart of the human body contracts, and controls the electromagnet to apply an attractive force to the permanent magnet to promote the diastole when the heart of the human body relaxes.

As a preferable technical scheme, the normal beating rhythm of the human heart is preset in the controller, and when the sensor monitors that the human heart stops beating, the controller can control the electromagnet to apply repulsive force or attractive force to the permanent magnet according to the preset normal beating rhythm of the human heart to drive the heart to contract or relax.

Preferably, the inner membrane and/or the outer membrane support body is a pocket-shaped structure capable of being sleeved on the surface of the heart of the human body.

Preferably, the inner membrane is a soft elastic membrane, and the hardness of the outer membrane support is greater than that of the inner membrane.

According to the preferable technical scheme, the permanent magnets are of arc-shaped structures so as to be attached to the surface of the heart of a human body through the inner membrane, the electromagnets are of arc-shaped structures matched with the corresponding permanent magnets, and each electromagnet is formed by combining one or more electromagnetic coils.

When the heart-protecting cover is used, the inner membrane covers and is sewn and fixed on the surface of a pericardial layer of a human heart, the outer membrane support covers the inner membrane, and the edge of the outer membrane support is sewn and fixed on the surface of the pericardial wall of the human heart.

Compared with the prior art, the electromagnetic heart beating assisting device of the utility model utilizes the inner membrane to fix at least two permanent magnets on the outer sides of the left ventricle and the right ventricle of the heart of the human body respectively, utilizes the outer membrane supporting body to fix at least two electromagnets on the relative positions of the corresponding permanent magnets respectively, supplies power to the electromagnets and adjusts the current and the direction, thereby enabling the electromagnet to exert repulsion or attraction on the corresponding permanent magnet, further actively promoting the contraction or relaxation of the heart of the human body, namely, the heart of the human body is assisted to beat, the controllability is strong, the heart of the human body recovers the normal blood pumping function, the heart failure symptom is relieved, the service life of a patient is prolonged, and the heart pump has very important application value, the heart-cutting-free surgical implant is simple in structure, small in size, convenient to replace, low in manufacturing and using cost, long in service life and easy to accept by doctors and patients, and the heart is not required to be cut off, and only needs to be implanted through a surgical operation. Through setting up the sensor, can utilize sensor real-time detection user heart beat rhythm, and then automatic control the utility model discloses supplementary human heart beats and keeps in step with user self heart beat rhythm. The normal beating rhythm of the human heart is preset in the controller, so that when a user stops beating the heart, the controller can drive the heart to contract and relax according to the normal beating rhythm of the human heart, the normal blood pumping function is kept, and danger is prevented. The inner membrane and the outer membrane support bodies are arranged to be pocket-shaped structures which can be sleeved on the surface of a human heart, so that the inner membrane and the outer membrane support bodies can be conveniently sleeved on the outer surface of the heart from bottom to top, the permanent magnets are just positioned at the outer sides of the left ventricle and the right ventricle of the human heart, and the electromagnets are just opposite to the corresponding permanent magnets. The inner membrane is arranged to be a soft elastic membrane, so that the inner membrane can be conveniently attached to the surface of the heart, and the hardness of the outer membrane support body is larger than that of the inner membrane, so that the electromagnet can be conveniently supported, fixed and prevented from shaking. The permanent magnet and the electromagnet are arranged to be mutually matched arc surfaces, so that the permanent magnet and the electromagnet are conveniently matched with the heart outline of a human body, the stress area is conveniently increased, and meanwhile, the thicknesses of the permanent magnet and the electromagnet are reduced.

The conception, the specific structure and the effects of the present invention will be further described with reference to the accompanying drawings, so as to fully understand the objects, the features and the effects of the present invention.

Drawings

Fig. 1 is a schematic structural view of an electromagnetic heart beat assist device according to the present invention;

fig. 2 is a schematic view showing a state of use of the electromagnetic heart beat assist device of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the following description will be made in detail by taking an intelligent medical instrument using the electromagnetic heart beating assisting device of the present invention as an example, and by referring to the accompanying drawings. It should be understood that the description of the specific embodiments is intended to be illustrative only and is not intended to be limiting.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or be indirectly connected to the other element through intervening elements.

As shown in fig. 1-2, an electromagnetic heart beat assist device includes:

the inner membrane 11 is coated and fixedly connected on the surface of the human heart 2 when in use;

an outer membrane support body 12 which covers the outer side of the inner membrane 11 when in use and has a gap with the inner membrane 11, and the edge of the outer membrane support body 12 is fixedly connected with the surface of the human heart 2;

the permanent magnets 13 are fixedly connected to the outer side of the inner membrane 11, the number of the permanent magnets 13 is two, one permanent magnet 13 is positioned on the outer side of a left ventricle 21 of the human heart 2, and the other permanent magnet 13 is positioned on the outer side of a right ventricle 22 of the human heart 2;

the electromagnets 14 are fixedly connected to the inner side of the outer membrane support body 12 and can be supported and fixed through the outer membrane support body 12, and the electromagnets 14 and the permanent magnets 13 are arranged in a one-to-one correspondence and opposite mode when in use;

and the battery and controller 15 is connected with the electromagnet 14 through an electric wire 16 and is used for supplying power to the electromagnet 14 and adjusting the current magnitude and direction, so that the electromagnet 14 can apply repulsion or attraction to the corresponding permanent magnet 13, and further the human heart 2 is driven to contract or relax.

The utility model discloses an electromagnetic heart beat auxiliary device, utilize inner membrance 11 to fix two permanent magnets 13 respectively in the outside of human heart 2's left ventricle 21 and right ventricle 22, utilize adventitia supporter 12 to fix two electro-magnets 14 respectively in the relative position that corresponds permanent magnet 13, through for electro-magnet 14 power supply and regulation electric current size and direction, thereby can make electro-magnet 14 exert repulsion or suction to corresponding permanent magnet 13, and then can initiatively promote human heart 2 to contract or diastole, namely assist human heart 2 to beat, and the controllability is strong, make human heart 2 resume normal pump blood function, can improve the heart failure symptom, prolong patient's life-span, have very important using value, and simple structure, small in size, need not excise heart 2, only need surgery to implant, it is convenient to change, make use cost low, long service life, the doctor and the patient can accept easily.

As a preferred embodiment, the electromagnetic heart beat assisting device further comprises a sensor (not shown in the figure), the sensor is connected with the controller, and the sensor can monitor the beat rhythm of the human heart 2 in real time and send data to the controller, so that the controller controls the electromagnet 14 to apply a repulsive force to the permanent magnet 13 to promote the contraction of the human heart 2 when the human heart 2 contracts, and controls the electromagnet 14 to apply an attractive force to the permanent magnet 13 to promote the relaxation of the heart 2 when the heart 2 relaxes. Through setting up the sensor, can utilize sensor real-time detection user heart 2 to beat the rhythm, and then automatic control the utility model discloses supplementary human heart 2 beats and keeps in step with user self heart 2 beats rhythm.

In a preferred embodiment, a normal pulsation rhythm of the human heart 2 is preset in the controller, and when the sensor detects that the human heart 2 stops jumping, the controller can control the electromagnet 14 to apply repulsive force or attractive force to the permanent magnet 13 according to the preset normal pulsation rhythm of the human heart 2 so as to drive the heart 2 to contract or relax. The normal beating rhythm of the human heart 2 is preset in the controller, so that when the heart 2 of a user stops beating, the controller can drive the heart 2 to contract and relax according to the normal beating rhythm of the human heart 2, the normal blood pumping function is kept, and danger is prevented.

In a preferred embodiment, the inner membrane 11 and the outer membrane support 12 are pocket-shaped structures that can be fitted over the surface of the human heart 2. The inner membrane 11 and the outer membrane support 12 are arranged to be pocket-shaped and can be sleeved on the surface of the human heart 2, so that the inner membrane and the outer membrane support can be conveniently sleeved on the outer surface of the heart 2 from bottom to top, the permanent magnets 13 are just positioned at the outer sides of the left ventricle and the right ventricle of the human heart 2, and the electromagnets 14 are just opposite to the corresponding permanent magnets 13.

In a preferred embodiment, the inner membrane 11 is a soft elastic membrane, and the outer membrane support 12 has a hardness greater than that of the inner membrane 11. The inner membrane 11 is a soft elastic membrane so as to be convenient to cling to the surface of the heart 2, and the hardness of the outer membrane support body 12 is larger than that of the inner membrane 11 so as to be convenient to support, fix and prevent the electromagnet 14 from shaking.

In a preferred embodiment, the permanent magnets 13 are in a cambered surface structure so as to be attached to the surface of the human heart 2 through the inner membrane 11, the electromagnets 14 are in a cambered surface structure matched with the corresponding permanent magnets 13, and each electromagnet 14 is formed by combining one or more electromagnetic coils. The permanent magnet 13 and the electromagnet 14 are arranged to be arc surfaces matched with each other, so that the heart 2 contour of the human body can be matched conveniently, the stress area can be increased conveniently, and meanwhile, the thicknesses of the permanent magnet 13 and the electromagnet 14 are reduced.

The surface of the human heart may be understood as the parietal pericardium, the visceral pericardium or other structures located on the surface of the heart. In use, the inner membrane 11 is covered and sutured to the surface of the pericardial layer of the human heart 2, the outer membrane support 12 is covered outside the inner membrane 11, and the edge of the outer membrane support 12 is sutured to the surface of the pericardial layer of the human heart 2.

The utility model discloses electromagnetic type heart is beaten auxiliary device can implant the installation through the surgery operation, and concrete mode is: the pericardium of the heart 2 of the user is cut open, the inner membrane 11 is implanted into the pericardial cavity, the surfaces of the inner membrane 11 and the pericardial visceral layer 23 are sutured and fixed, the outer membrane support body 12 is implanted into the pericardial cavity, the edge of the outer membrane support body 12 and a pericardial wall layer 24 at the root of the heart 2 are sutured and fixed, and the electromagnet 14 is opposite to the permanent magnet 13. The outer membrane support 12 may occupy a certain volume if it is made of a non-deformable or hard-to-deform material, and may be implanted by a thoracotomy, and the outer membrane support 12 may be implanted by a minimally invasive surgical operation if it is made of a deformable material and molded after being placed in the thoracic cavity, or made of a compressible and expandable material, or made of a memory material. The battery and controller 15 can be placed at the bottom of the left chest and the wires 16 can be passed through the left intercostal muscles, and the battery and controller 15 can be placed at the left chest subcutaneously or externally.

The above description is only a preferred embodiment of the application and is illustrative of the principles of the technology employed. It will be understood by those skilled in the art that the scope of the present invention is not limited to the specific combination of the above-mentioned features, but also covers other embodiments formed by any combination of the above-mentioned features or their equivalents without departing from the spirit of the present invention. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Claims

1. An electromagnetic heart beat assist device, comprising:

2. The electromagnetic heart beat assisting device according to claim 1, further comprising a sensor connected to the controller, wherein the sensor is capable of monitoring heart beat rhythm of the human body in real time and sending data to the controller, so that the controller controls the electromagnet to apply a repulsive force to the permanent magnet to promote systole and controls the electromagnet to apply a suction force to the permanent magnet to promote diastole when systole.

3. The electromagnetic heart beat assisting device according to claim 2, wherein a normal beat rhythm of the human heart is preset in the controller, and when the sensor detects that the human heart is beating, the controller can control the electromagnet to apply a repulsive force or a suction force to the permanent magnet according to the preset normal beat rhythm of the human heart to drive the heart to contract or relax.

4. The electromagnetic heart beat assisting device according to claim 1, wherein the inner membrane and/or the outer membrane support is a pocket-like structure that can be fitted over a surface of a human heart.

5. The electromagnetic heart beat assisting device according to claim 1, wherein the inner membrane is a soft elastic membrane, and the outer membrane support has a hardness greater than that of the inner membrane.

6. The electromagnetic heart beat assisting device according to claim 1, wherein the permanent magnets are of a cambered surface structure so as to be attached to the surface of the human heart through the intima, the electromagnets are of a cambered surface structure matched with the corresponding permanent magnets, and each electromagnet is formed by combining one or more electromagnetic coils.

7. The electromagnetic heart beat assisting device according to claim 1, wherein the inner membrane is covered and sutured to a surface of a pericardial layer of a human heart, and the outer membrane support covers the inner membrane and has an edge sutured to a surface of the pericardial layer of the human heart.